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Telecom, technology and aviation industry leaders join forces to create the HAPS Alliance to connect more people, places and things by using the stratosphere

A group of global industry leaders is forming the HAPS Alliance, an association of world-leading telecommunications, technology, aviation and aerospace companies united in promoting the use of high-altitude vehicles in the Earth’s stratosphere to eliminate the digital divide and bring connectivity to more people, places and things worldwide.

Members who have committed to join the HAPS Alliance include

• SoftBank Corp.’s HAPSMobile Inc.
• Alphabet’s Loon LLC
• AeroVironment Inc.
• Airbus Defence and Space
• Bharti Airtel Limited
• China Telecom Corporation Limited
• Deutsche Telekom AG
• Intelsat US LLC
• Nokia Corporation
• SoftBank Corp.
• Telefónica S.A.
• Telefonaktiebolaget LM Ericsson

The HAPS Alliance is being created so member companies can

• collectively advocate for High Altitude Platform Station (HAPS) business development with the relevant authorities in various countries
• build a cooperative HAPS ecosystem
• develop common product specifications and promote the standardization of HAPS network interoperability

All of these activities will be key to the Alliance’s aim of addressing diverse social issues and creating new value by providing telecommunications network connectivity worldwide through the utilization of high altitude vehicles.

The Alliance, originally an initiative from HAPSMobile and Loon, will have members from participating leading companies across the aerospace, technology and telecom industries to carry out the Alliance’s activities.

The launch of the HAPS Alliance follows an April 2019 announcement between HAPSMobile and Loon where the companies formed a strategic alliance to advance the use of high-altitude vehicles.

High-altitude network connectivity platforms operate in the stratosphere — above ground infrastructure but below satellites — allowing for near ubiquitous coverage that avoids ground clutter and significant latency issues.

These advantages make such vehicles a promising solution for expanding mobile coverage to areas where connectivity is lacking — mountainous terrain, remote islands, marine regions and developing countries — as well as for IoT and 5G use-cases. The HAPS Alliance seeks to create an ecosystem to support next-generation global connectivity needed to revolutionize the world’s mobile networks.

The Institute of Navigation (ION) has published its Global Navigation Satellite Systems (GNSS) Software Defined Radio Metadata Standard document.

According to ION, The standard is the product of a three-year long effort of the ION GNSS SDR Standard Working Group and defines parameters and schema to express the contents of SDR sample data files. The standard promotes the interoperability of GNSS SDR data collection systems and processors, ION added.

“In recent years there has been a proliferation of software defined radio data collection systems and processing platforms designed for Global Navigation Satellite System receiver applications or those that support GNSS bands,” ION said in a press release. “For post-processing, correctly interpreting the GNSS SDR sampled datasets produced or consumed by these systems has historically been a cumbersome and error-prone process. This is because these systems necessarily produce datasets of various formats, the subtleties of which are often lost in translation when communicating between the producer and consumer of these datasets. This specification standardizes the metadata associated with GNSS SDR sampled data files and the layout of the binary sample files.”

The standard is free and can be found here.

Semtech Corporation, supplier of high-performance analog and mixed-signal semiconductors and advanced algorithms, has launched LoRa Edge, a versatile and low-power software defined LoRa-based platform.

Semtech said LoRa Edge will enable a wide portfolio of applications for indoor and outdoor asset management, targeting industrial, building, home, agriculture, transportation and logistics markets.

The first product from this portfolio is a geolocation solution for development of internet of things (IoT) devices for asset management applications. It features low-power Wi-Fi and GNSS sniffing capabilities combined with LoRa Cloud geolocation and device management services to significantly reduce the cost and complexity of locating and monitoring IoT assets.

“Semtech continually delivers internet of things (IoT) solutions that simplify and accelerate the development of LPWAN applications,” said Pedro Pachuca, director of IoT Wireless in Semtech’s Wireless and Sensing Products Group. “LoRa Edge and LoRa Cloud geolocation services enable customers to develop ultra-low power applications for a variety of industries and will expand the mass adoption of LoRa in the IoT ecosystem.”

Over the next decade, 500 billion devices are expected to connect to the internet (according to Cisco), as organizations continue to shift towards a more IoT-focused business strategy, and the majority of those IoT devices require some form of localization capability either at point of install or through the assets life.

The LoRa Edge geolocation platform will enable solution providers to leverage the unique localization capabilities of LoRa as well as GNSS and Wi-Fi scanning capabilities from a single chip solution, allowing customers to choose the best localization tool for the application task they are addressing.

By removing the need for incremental GNSS and Wi-Fi components, LoRa Edge reduces the bill of material (BOM) costs of devices and significantly reduces design and procurement complexity, Semtech said.

The first LoRa Edge chipset targeted with geolocation (LR1110) is available today; more products from this portfolio will be released in the first half of this year.

Product Features

Multi-Purpose Radio Front-End

• 150 – 2700 MHz continuous frequency synthesizer range
• GPS/BeiDou scanning
• Wi-Fi passive scanning

Low-Power LoRa/(G)FSK RF Transceiver

• Worldwide frequency bands support in the range 150 – 960 MHz
• High power PA path +22 dBm
• High efficiency PA path +15 dBm
• Fully compatible with the LoRaWAN standard

Cryptographic Engine

• Hardware support for AES-128 encryption/decryption based algorithms
• Handling device parameters such as DevEUI and JoinEUI
• Protects confidential information such as encryption keys
• Stores NwkKey, AppKey, as defined in the LoRaWAN standard

Quectel Wireless Solutions is collaborating with Microsoft and Qualcomm Technologies to integrate its new LPWA module BG95 with Microsoft’s Azure Device SDK.

The integration will provide direct and secure connections to Azure IoT Hub and provide full support for Azure device management capabilities.

Targeting global markets, the BG95 module is a cost-optimized, highly-integrated variant supporting integrated GNSS, Cat M1, Cat NB2 and EGPRS (also called EDGE). The module complies with 3GPP Release 14 and delivers improved capabilities in power consumption, data rates and hardware-based security.

The BG95 cellular module is based on the Qualcomm 9205 LTE modem, to be integrated with Microsoft’s Azure Device software development kit (SDK). As a result, customers can connect their BG95 devices to the Microsoft Azure cloud where they can build, manage and deploy internet of things (IoT) solutions at scale, significantly accelerating time to market.

By integrating RAM/flash, an ARM Cortex A7 processor supporting ThreadX, the BG95 is engineered to reduce power consumption significantly in idle mode.

By doing this, the BG95 has the potential to support decade-plus battery life, which is critical for IoT devices serving long life spans, such as asset trackers, smart meters, smart city sensors, home security and wearable trackers.

Additionally, Azure IoT is built for security. It simplifies the complexity of IoT security solutions with built-in protection at each stage of deployment (including cloud services and devices) and minimizes security weaknesses wherever they exist. Leveraging Azure IoT security features, Quectel BG95 will offer IoT devices end-to-end security capability in order to prevent potential risks.

“We’re excited for the Azure edge device ecosystem to continue to grow. Our partnership with Quectel and Qualcomm Technologies will deliver what our customers need — bringing together ultra-low power cellular modules and Azure to drive their digital transformation,” said Roanne Sones, corporate vice president at Microsoft.

“The BG95 module is the first Qualcomm 9205 platform to support IoT Plug and Play, accelerating LPWAN solution deployments like smart meters and asset trackers that connect seamlessly to our IoT Central offering,” Sones said.

“With its cutting-edge performance and power-saving capabilities, the Qualcomm 9205 LTE Modem is the gold standard for multimode IoT modules looking to offer NB-IoT, Cat-M1, GPRS, and GNSS connectivity,” said Jeffery Torrance, vice president, business development, Qualcomm Technologies, Inc. “We are proud to continue our long-standing collaboration with Quectel to jointly drive the IoT forward.”

“We are happy that the BG95-M3 has been verified on Microsoft Azure IoT Plug and Play. This validates our ability to jumpstart customers’ IoT projects with pre-tested modules and operating system combinations. Leveraging our close relationship with Microsoft and Qualcomm Technologies, we will jointly provide more integral ‘Device-Cloud’ solutions to customers,” said Doron Zhang, Chief Operation Officer, Quectel. “As one of the first wave Azure IoT PnP partners, Quectel has worked with Microsoft on LTE Mobile Broadband (MBB) modules, which have been widely adopted by top laptop OEMs. In the future, we will extend the partnership to more fields, such as Artificial Intelligence (AI) and Intelligent Edge, in order to help the Microsoft partner ecosystem connect their devices even more intelligently.”

Robotic Research LLC, a leading provider of autonomy and robotic technologies, will begin testing fully autonomous low-speed shuttles that are totally unmanned in the second quarter of this year.

Current commercial applications of low-speed shuttles use onboard safety attendants to monitor the safety inside and outside the vehicle. Robotic Research plans to start testing without onboard attendants.

The first step is to have the attendants in fixed on-site locations, with the future goal to move attendants to an offsite safety monitoring facility.

“Through our work with the U.S. government over the past four years, we have already demonstrated that fully autonomous trucks are a reality. We are committed to making our shuttle and bus manufacturing partners successful by accelerating state-of-the-art technologies for unmanned vehicles ahead of regulatory agencies’ progress,” said Alberto Lacaze, president of Robotic Research.

“The level of safety certification and redundancy necessary to drive fully autonomous vehicles is a significant undertaking that needs to be designed from the top down. Just adding more ADAS is not a reasonable or cost-effective pathway to full autonomy,” Lacaze said. “The advancements driven by the Robotic Research team will provide a product that significantly reduces the cost of operation and therefore improves market size.”

Current local, state and federal regulations for most commercial shuttle operations require the safety attendant to be inside the cab of the vehicle. However, many transit operators are seeking to change these regulations to allow remote attendants to oversee system safety operations. The change is integral to the viability of low-speed shuttles, which are an innovative solution to the first/last mile problem, which is the distance between a traveler’s origin or destination, and a transit station or stop.

Robotic Research has been developing and testing unmanned, autonomous operations for a wide range of vehicles for nearly a decade. The company currently provides autonomy kits that fully automate logistics convoy trucks for the U.S. government and several of its allied nation partners. Nearly 100 trucks have already been delivered. The tests for these vehicles have included operations with no safety attendants on board, with a single operator monitoring three unmanned vehicles.

Robotic Research’s AutoDrive autonomy kit is platform agnostic and can be retrofitted to vehicles of all sizes, from small, portable robots to large trucks and buses. The system provides autonomous functionality on surfaces ranging from urban-improved roads to off-road terrain, all while the vehicle is collecting and analyzing data to better enhance the future of autonomous vehicles and transportation.

Robotic Research’s technology provides automation to one of the largest international shuttle providers as well as to the largest U.S. manufacturer of commercial buses. The company’s AutoDrive kit also supports various autonomy programs in commercial and government sectors and is currently operating in communities and cities around the globe, including 30 states and four continents.

The Optech CL-360 has joined the ranks of Lidar USA Snoopy systems.

The Snoopy CL-360 has been meticulously designed for integration on backpack, vehicle and UAV applications. Weighing 5 kilograms fully assembled, the Snoopy CL-360 is capable of delivering highly accurate results, up to +/-0.01 feet on paved surfaces from a vehicle.

The system has a scan line rate of 250 Hz with a 500-kHz data rate, giving a uniform result along and across track. The systems are easily configurable with multiple scanners (similar to internet of things applications) to avoid occlusions.

“We are pleased to again partner with LidarUSA in their innovative approach to UAV integration with the addition of our CL-360 to their product portfolio. Featuring true 360-degree scanning without blind spots, CL-360 integrated by LidarUSA will provide an exciting addition to the UAV marketplace,” said Optech Executive Vice President and General Manager Michel Stanier.

Users can also benefit from a UAV deployment, achieving scans with usable data as much as 60 degrees off nadir (widths of more than 1,100 feet while scanning at the 400-foot ceiling). The small beam size of 0.3 mrad allows the CL-series to reliably collect ground points (such as on or near the dirt through vegetation) while also providing better detection of fine linear features such as power lines and railroad tracks.

The integration of the CL-360 into the Snoopy series of systems from Lidar USA is expected to be a huge plus to the mapping community in 2020, according to Lidar USA. Users can expect to see the benefit of decreased field-collection effort and increased product quality resulting in a growing and profitable business.

“As more technologies embrace lidar collection to reduce their field time, we expect to see the CL-series become the ‘go to’ solution for many of them,” said Jeff Fagerman of Lidar USA. “The CL-series provides the accuracy and point density often necessary to meet the client’s every growing demands for more, more, more. By designing the system for car and UAV, as well as multiple configurations (two or more systems running together), our users will greatly benefit where they feel it most — the bank.”

L3Harris Technologies has reached a major milestone in the U.S. Air Force’s Navigation Technology Satellite-3 (NTS-3) project — passing the preliminary design review that defines the spacecraft’s path to delivery and allows the program to move to the next phase of development.

NTS-3 is an experimental program examining ways to improve the resiliency of the military’s positioning, navigation and timing capabilities. It will also develop key technologies relevant to the Global Positioning System (GPS) constellation, with the goal of future transition to the GPS IIIF program.

In collaboration with the Air Force Research Laboratory, Space and Missile Systems Center, and United States Space Force, L3Harris is combining experimental antennas, flexible and secure signals, increased automation, and use of commercial command and control assets.

“The NTS-3 vanguard is an experimental, end-to-end demonstration of agile, resilient space-based positioning, navigation, and timing,” said Arlen Biersgreen, Air Force NTS-3 program manager. “It has the potential for game-changing advancements to the way the Air Force provides these critical capabilities to warfighters across the Department of Defense. The commitment demonstrated by United States Space Force to partner with AFRL and support technology transition was a key element in NTS-3 being designated as an Air Force vanguard in September 2019.”

The Space Enterprise Consortium selected L3Harris for the $84-million contract in 2018 as the prime system integrator to design, develop, integrate and test NTS-3, including ground mission applications.

“We have moved from contract award to finishing an early design review in under one year, which is an amazing accomplishment for a satellite development program that normally takes twice that amount of time,” said Ed Zoiss, President, Space and Airborne Systems, L3Harris. “We have proven we can move quickly to support the Air Force’s go-fast mission requirements.”

L3Harris has more than 40 years of experience transmitting GPS navigation signals. The company’s technology has been onboard every GPS satellite ever launched.

Turkey has opened GNSS base station in Antarctica, according to Sputnik News. The station can track changes in the location of icebergs and transmit photos of Antarctica’s surface, as well as process data from GPS, GLONASS and Galileo.

“A GNSS satellite navigation base station was set up within the framework of the fourth Turkish scientific expedition to Antarctica,” said Turkish Industry and Technology Minister Mustafa Varank, as quoted by the national Anadolu news agency. “A group of specialists from the Turkish General Directorate of Mapping has built Turkey’s first GNSS base station abroad.”

The Fourth Antarctic Expedition of Turkey began on Feb. 9 under the coordination of the Scientific and Technological Research Council (TUBITAK) Polar Research Institute. The GNSS station operates on Dismal Island, 73 kilometres (45 miles) from Horseshoe Island, where the temporary Turkish science base is located.

The 24-member Turkish research team joins 15 scientific projects in the Earth, life, and marine sciences. The expedition is being conducted under the auspices of the Turkish Presidential Administration and the Ministry of Industry and Technology and coordinated by the TUBITAK.

On Feb. 12, the White House released an “Executive Order on Strengthening National Resilience through Responsible Use of Positioning, Navigation, and Timing Services.”

It is gratifying to see White House attention to this issue. The increase in public awareness it brings will benefit individual users and the nation as a whole.

The order also hints at market driven solutions that could quickly improve America’s PNT resilience.

Needless delays

Unfortunately, the order fails to direct immediate action on this critical national and economic security issue. Instead it needlessly pushes most action and responsibility off for a year or more to do “more study.”

This is hard to understand as most of the “more study” has already been completed. For example, the order tells the Department of Commerce to take up to a year to examine PNT use in various sectors, and identify vulnerabilities and user needs. The Department of Homeland Security has already completed a National Risk Assessment and, according to congressional staff, has recently completed a report on user requirements mandated in 2017’s National Defense Authorization Act.

The Office of Science and Technology Policy is given a year to develop a plan to test robust and resilient non-GNSS PNT services (but is not required to actually do any testing). Congress mandated such a test program in 2017 and funded it with $10 million in 2018. After much delay, the Department of Transportation will complete the testing in May of this year.

The order gives the Department of Commerce six months to make available a time source to support critical infrastructure. For more than 60 years, the nation’s master clock has been available to users at the department’s NIST Laboratory in Boulder, Colorado.

Note the challenge has not been the clock, but that the nation has no way — other than vulnerable GPS signals — to distribute time at the needed level of accuracy to millions of critical infrastructure nodes. Government studies in 2007 and 2014 determined that the best way to do this was with a ground-based system. The Department of Transportation’s ongoing testing program is examining this issue again.

Market-driven solutions

Aside from increasing public awareness, the best thing the Executive Order does is to point a way forward for market-driven resilient PNT solutions.

The order calls for federal contracts to (in 21 months, if everyone does their jobs on time) require that vendors use existing and new resilient PNT sources.

If this eventually happens, the government could leverage its enormous influence in the market and stimulate creation of one or more commercial distribution systems for resilient, non-GNSS PNT. This is a great concept, and very much in keeping with America’s tradition of letting market forces solve some of its biggest problems.

But this solution will not spring into life on its own.

No commercial entity will invest tens of millions of dollars, or more, in a PNT system without assurance in advance of an income stream. Especially since federal contracting officers can and will waive the requirement if offerors cannot reasonably meet it.

If stimulating a market solution is the administration’s intent, it must stay actively involved and encourage the process for some time to come.

This includes complying with the 2018 law that requires establishment of at least one wireless, terrestrial, difficult-to-disrupt source to back up the timing signals provided by GPS.

Fortunately, this can be done by leveraging the free market at minimal cost and with little administrative effort.

By contracting to subscribe to a commercial service that will provide resilient PNT signals, the government need only invest a relatively small yearly sum using a fairly simple contract vehicle. Such a contracting technique has been used before with great success.

In 2007 the Federal Aviation Administration (FAA) did this as a way to establish its ADS-B aviation tracking and safety network. Once the subscription contract was let, the commercial provider was able to get financing and quickly build out the system.

Today, the FAA gets the information it needs, doesn’t have the headache of owning and maintaining a large network, and even shares in the revenue the system owner earns from selling data to other companies.

Additional leadership needed

It is important to remember that, regardless of the issue, presidential pronouncements are not enough.

In 2004, President G.W. Bush directed a number of actions to protect the nation’s critical PNT, including establishment of a GPS backup capability. While 16 years later his directive is still official executive branch policy, that mandate and many others from his order are still unexecuted.

Real improvements to PNT resilience and our nation’s security depend not on one-time pronouncements, but continued leadership focus and engagement.

This is always a challenge for initiatives driven by the White House. It will be doubly so in this case as there is no clear department leader for civil PNT issues the administration can rely on while it attends to the next issue of the day.

The UK’s emergency service responders and other critical services could be set for more resilient time systems through the National Timing Centre.

The United Kingdom has established a new timing center to reduce reliance of public services and its economy on GNSS satellites. The center uses a network of atomic clocks housed at secure locations, and consists of a team of researchers based at sites across the UK.

The National Timing Centre will provide additional resilience for accurate timing, which underpins many everyday technologies including emergency response systems, 4G/5G mobile networks, communication and broadcast systems, transport, the stock exchange and the energy grid — all of which depend on precision timing from GNSS.

A large-scale GPS failure would cause a £1 billion a day economic impact to the UK. Loss of this accurate data would also have severe and life-threatening effects, such as on getting ambulances to patients or getting power to homes around the country. The center’s land-based technologies will improve the UK’s resilience and provide important back-up.

The UK’s current dependence on satellite technologies has been identified by the government as a potential security risk if a satellite were to experience a failure. The Blackett Review in 2018 looked at the UK’s vulnerabilities to over-reliance on Global Navigation Satellite Systems (GNSS).

National Timing Centre to add resilience

The government is investing £36 million to create the National Timing Centre, which will ensure the UK economy and public services have additional resilience to the risk of satellite failure. The investment will build a resilient network of clocks across the UK. It includes £6.7 million which will be made available via Innovate UK funding calls to SMEs and industry to innovate around timing and clocks.

Science Minister Amanda Solloway announced the center on Feb. 19. “Our economy relies on satellites for accurate timing,” she said. “Without satellites sending us timing signals, everything from the clocks and maps on our phones, to our emergency services and energy grid would be at risk. I’m delighted that this world-first centre will see our brightest minds, from Surrey to Strathclyde, working together to reduce the risks from satellite failure.”

“The failure of these systems has been identified as a major risk, and The National Timing Centre programme will help to protect both vital services and the economy from the disruption this would cause while delivering considerable economic benefits,” said UK Research and Innovation Chief Executive Professor Sir Mark Walport.

“We are proud to be leading the way in providing trusted and assured time and frequency,” said National Physical Laboratory CEO Pete Thompson. “The work undertaken by the team here has ensure the National Timing Centre programme will provide huge benefits to society, whilst underpinning secure applications in the future.”

The center also includes researchers at the University of Birmingham, the University of Strathclyde, University of Surrey, BT Adastral Park, Suffolk, BBC, Manchester, and the National Physical Laboratory in Teddington.

The £76 million investment furthers the government’s commitment to significantly boost R&D investment across every part of the UK, including funding transformational technologies and increasing the number of researchers.

The funding is provided through the Strategic Priorities Fund, which supports high-quality discipline research and development priorities, with investment also going towards autonomous systems and national collections.

Alongside investment in the new center, the UK government is investing a further £40 million in a new research programme, Quantum Technologies for Fundamental Physics.

Total investment through the National Quantum Technologies Programme is set to pass £1 billion since its inception in 2014.